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Name: ______________________
Relationship Between Gas Variables Gas Laws Simulation
Introduction: Scientists in the late 1800’s noted relationships
between various variables related to
gases (pressure, volume, temperature), and the number of gas
particles in the sample being studied. They were able to figure out
that it was easier to study relationships if they varied only two
parameters at a time and “fixed” (held constant) the others. For
example, they would study the relationship between pressure and
volume (variables) and held temperature constant (“fixed”). After
recording the data and graphic analysis, a trend was
determined.
These experiments would be difficult to complete a laboratory
because it is complicated to isolate the parameters. Using a gas
simulation you will be able to create different scenarios and
collect data for each combination. You will be working with a
fellow scientist and determine the various gas laws that were
created years ago.
Objectives: • Design experiments to measure the relationships
between pressure, volume,
and temperature. • Create graphs based on predictions and
observations. • Make qualitative statements about the relationships
between pressure, volume,
and temperature using molecular models.
Directions: Create mini experiments using the Gas Simulation
(under my website: “Links”): Following the instructions below, make
observations based on the gas simulation on the website. To
activate the activity, press run now and press keep (bottom of
computer). Do not update Java, press later for the update.
Part I: Gas Particle Behavior at Constant Temperature
Boyle’s Law
In 1642 Evangelista Torricelli, who had worked as an assistant
to Galileo,
conducted a famous experiment demonstrating that the weight of
air would support a column of mercury about 30 inches high in an
inverted tube. Torricelli’s experiment provided the first
measurement of indivisible pressure of air. Robert Boyle, a
“skeptical chemist” working in England, was inspired by
Torricelli’s experiment to measure the pressure of air when it was
compressed
or expanded. The results of Boyle’s experiments were published
in 1662 and became essentially the first gas law-a mathematical
equation describing the relationship between the volume and
pressure of air.
What is Boyle’s law and how can it be demonstrated?
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Directions: 1. Slowly add gas particles to the vessel by raising
the pump and bringing it down once.
2. On the right toolbar, make your constant parameter
“temperature.” List the two variables that will be observed in this
activity
Constant Parameter Temperature
________Kelvin
Independent Variable
_____________
Dependent Variable
______________
3. By moving the man on the left and the movable ruler tool
(click on tools & options –
measurement tools-ruler), vary the volume and observe the change
in pressure. Make sure you allow the temperature to readjust to the
original value. Complete the following data table based on your
observations:
Relationship
P vs. V PV= K
VOLUME
Let’s use the width (nm) to express the volume of the gas.
PRESSURE (atm) Read the pressure gauge
and record the value Initial
V= 4 nm
Final
V= 8 nm
Conclusions: What type of relationship exists between pressure
and volume
(indirect or direct)? _______________
Label the x-axis and y- axis. Draw a graph representing the
relationship.
Graphic Representation
Practice Problem: A sample of oxygen gas has a volume of 150.0
mL when its pressure is 0.947 atm. What is will the volume of the
gas be at a pressure of 0.987 atm if the temperature remains
constant? (Using a highlighter, highlight your final answer)
Formula Mathematical Set-up & Answer
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Interpret Graphs Boyle’s Law
Study the line graph below. Volume in liters (L) is on the
x-axis. Pressure in kilopascals (kPa) is on the y-axis. This graph
shows the relationship between the pressure and volume
of a gas described by Boyle. The drawings can help you picture
the volume of the gas at specific points. The experiment was done
at Standard Temperature.
1. Complete the table.
Number of Gas Particles
Pressure (kPa)
Volume (L)
V1P1
V2P2
V3P3
2. Look at the drawing at point V2P2. What happened to the
volume in the cylinder?
___________________________________________________________________________________
What happened to the amount of gas?
___________________________________________________________________________________
3. How did the volume of the gas change between Points V1P1 and
V2P2?
____________________________________________________________________________________
How did the pressure change?
____________________________________________________________________________________
4. How does an increase in the volume of a gas affect its pressure?
Assume the temperature is constant.
_________________________________________________________________________________________
____________________________________________________________________________
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5. What would the pressure be if the volume were 1.5 L?
________________ 6. Is the relationship between the pressure and
volume of a gas a direct one or an inverse one?
_____________________ 7. Using the combined Gas Law Formula below
cross out the variable that was kept constant in Boyle’s
experiment. Practice Problems: a. A gas with a volume of 2.2 L at
140 kPa expands to fill a 4.4-L container. What is the pressure in
the new container? What is the pressure in the new container? The
temperature does not change.
Formula Mathematical Set-up & Answer
b. A balloon contains 30.0 L of helium gas at 103 kPa. What is
the volume of the helium when the balloon rises to an altitude
where the pressure is only 25.0 kPa? (Assume that the temperature
remains constant.)
Formula Mathematical Set-up & Answer
c. When a piston is pushed down in a cylinder, the pressure on
the gas in the cylinder increases from standard pressure to 3.7
atm. The initial volume is 23.5 L. What is the final volume?
Formula Mathematical Set-up & Answer
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Part II: Gas Particle Behavior at Constant Pressure
Charles’ Law Application of the gas laws are important in
physiology, meteorology, scuba diving, even hot-air ballooning.
Charles’s law, which describes how the volume of a gas changes as
it is heated or cooled, was inspired by one of these applications,
the first sensational flight in history of hot –air ballooning.
1. RESET: On the right toolbar, now make your constant parameter
“pressure.” List the two variables that will be observed in this
activity.
Constant Parameter Pressure
(Approximate)
__________ atm
Independent Variable
_____________
Dependent Variable
______________
2. Using the thermometer (use the heat control to adjust
temperature) and ruler, collect data to investigate the
relationship between volume and temperature of a gas. Make sure you
allow the pressure to readjust to the original value (constant
pressure).
Relationship
T vs. V
V/T = K
TEMPERATURE VOLUME Let’s use the width (nm) to express
the volume of the gas. Initial
86 K
__________nm
Final
172 K
__________nm
Conclusions: What type of relationship exists
between temperature and volume (indirect or direct)?
_______________ Label the x-axis and y- axis.
Draw a graph representing the relationship.
Graphic Representation
Practice Problem: A sample of neon gas occupies a volume of 752
mL at 300 K. What will the gas occupy at 355 K if the pressure
remains constant?
Formula Mathematical Set-up & Answer
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Interpret Graphs Charles’s Law
Study the line graph below. This graph shows the relationship
between the volume and the temperature of a gas at constant
pressure.
1. Volume is the variable on the y-axis. What units are used for
the volume? ___________ 2. What is the variable on the x-axis?
___________________ What are the units? __________ 3. What is the
volume of the gas when the temperature is 300 K? _____________ 4.
How did the values of the temperature of the gas change between T1
and T2?
_____________________________________________________________________________________
How did the volume change?
_____________________________________________________________________________________
5. When the temperature is 600 K, what is the volume? _____________
6. Use the volume at 600 K to predict the volume at 1200 K. Explain
your answer. (Hint: How did the volume change when the temperature
went from 300 K to 600 K?)
__________________________________________________________________________________
______________________________________________________________________
7. How does an increase in the temperature of a gas affect its
volume? Assume the pressure is constant.
_____________________________________________________________________________________
8. Is the relationship between the volume and temperature of a gas
a direct or an inverse relationship? _______________________
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9. Using the combined Gas Law Formula below cross out the
variable that was kept constant in Charles’s experiment.
When you use Charles’s law, the temperatures must be in
kelvins!
Practice Problems: a. An inflated balloon has a volume of 3.85 L
at 240C. The balloon is placed in a refrigerator and cooled to
4.00C. What is the new volume of the balloon? Assume the pressure
does not change.
Formula
Mathematical Set-up & Answer
b. A 6.70 L sample of argon gas is in a cylinder with a piston
at STP (standard temperature and pressure). If the pressure is kept
constant, at what temperature will the volume of the gas be 7.30
L?
Formula
Mathematical Set-up & Answer
c. At 310C, the volume of gas in a small plastic bag is 0.115 L.
If you place the bag in a cooler at 120C, what is the new volume?
Assume the pressure is constant.
Formula
Mathematical Set-up & Answer
d. Nitrogen gas is transferred from a 12.1 L container to a 15.2
L container at constant pressure. The temperature of the gas in the
second container is 35.40C. what was the temperature in the first
container?
Formula
Mathematical Set-up & Answer
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Part III:
Gas Particle Behavior at Constant Volume Gay- Lussac’s Law
Gay-Lussac grew up during the period of the French Revolution.
This was a time when the science of chemistry also saw several
changes. The French Revolution directly affected Gay-Lussac. During
the revolution, his father was imprisoned and young Gay-Lussac was
sent to
the Ecole Polytechnique. This was an institution created by the
French Revolution to nurture scientists, especially for military
use.
1. RESET: On the right toolbar, now make your constant parameter
“Volume.” List the two variables that will be observed in this
activity
Constant Parameter
Volume
Variable #1
_____________
Variable #2
______________
.
Relationship T Vs. P
P/T = K
Temperature Pressure (atm)
(Approximate) Initial 40 K Final 80 K
What type of relationship exists
between temperature and pressure (indirect or direct)?
_______________ Label the x-axis and y- axis.
Draw a graph representing the relationship.
Graphic Representation
Questions: 1. Using the combined Gas Law Formula below cross out
the variable that was kept constant in Gay Lussac’s experiment.
When you use Gay-Lussac’s law, the temperatures must be in
kelvins!
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As the temperature of an enclosed gas increases, the pressure
increases, if the volume
is constant.
Practice Problems: a. The gas in a container is at a pressure of
3.00 atm at 298 K. Directions on the container warn the user not to
keep it in a place where the temperature exceeds 325 K. What would
the gas pressure in the container be at 325 K?
Formula
Mathematical Set-up & Answer
b. Aerosol cans carry labels warning not to incinerate (burn)
the cans or store them above a certain temperature. This problem
will show why it is dangerous to dispose of aerosol cans in a fire.
The gas in a used aerosol can is at a pressure of 103 kPa at 25oC.
If the can is thrown onto a fire, what will the pressure be when
the temperature reaches 928oC?
Formula
Mathematical Set-up & Answer
c. A pressure cooker containing kale and some water starts at
298 K and 101 kPa. The cooker is heated, and the pressure increases
to 136 kPa. What is the final temperature inside the cooker?
Formula
Mathematical Set-up & Answer
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Using the Combined Gas Law Formula
1. A beach ball is partly inflated to a volume of 23.3 L. The
temperature of the air in the ball is 305 K, and its pressure is
101.3 kPa. A swimmer holds the ball under water in a pool, where
the pressure is 131.3 kPa. The volume of air in the ball decreases
to 17.6 L. What happens to the temperature of the air in the
ball?
Formula
Mathematical Set-up & Answer
2. Neon gas at STP is compressed in a rigid container to a
volume of 84.6 L. What is the pressure of this gas at 88.5 L and
250C?
Formula
Mathematical Set-up & Answer
3. A gas has a volume of 275 L at 348 K. When it is cooled to
297 K, its pressure changes to 115 kPa and its volume decreases to
263 L. What was the original pressure of the gas?
Formula
Mathematical Set-up & Answer
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Part IV:
Number of Gas Particles(Moles) and Volume: Temperature and
Pressure Avogadro’s Law
This simulation cannot be performed. Therefore, predict the
relationship. Since volume is one of the variables, that means
the
container holding the gas is flexible in some way and can expand
or contract.
Relationship Number of gas
molecules(moles) versus Volume V = k n
* n is the amount of gas in moles
What happens to the volume of a balloon when helium from a tank
is added to the balloon?
____________________________________________________
What type of relationship exists between volume and number
of
moles (indirect or direct)? _______________
Label the x-axis and y- axis. Draw a graph representing the
relationship.
Graphic Representation
Avogadro’s law states that equal volumes of gases at the same
temperature and pressure contain equal numbers of molecules.
Practice Question: Which gas sample at STP has the same total
number of molecules as 2.0 liters of CO2(g) at STP?
(1) 5.0 L of CO2(g) (3) 3.0 L of H2S(g) (2) 2.0 L of Cl2(g) (4)
6.0 L of He(g)
Which gas sample at STP has the same number of molecules as a
2.0-liter sample of Cl2(g) at STP?
(1) 1.0 L of NH3(g) (3) 3.0 L of CO2(g) (2) 2.0 L of CH4(g) (4)
4.0 L of NO(g)
Using dimensional analysis, determine the volume of 3 moles of
neon gas at STP?
(Equivalence statement: 1 mole of any gas at STP = 22.4 L)
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Making Connections: Using your results, explain each of the
following scenarios. Make sure to refer to which graph can be used
as evidence for your answer. Also include references to pressure,
temperature, and volume in your responses.
1. In terms of gas particle behavior, explain why bicycle tires
seem more flat in the winter
than in the summer. 2. Explain why a can of soda pop explodes if
left in the hot sun.
3. A rigid container filled with a gas is placed in ice
(example: Oxygen tank found in
hospitals). What will happen to the pressure of the gas inside
the tank?
4. An infected tooth forms an abscess (area of infected tissue)
that fills with gas. The
abscess puts pressure on the nerve of the tooth, causing a
toothache. While waiting to see a dentist, the person with the
toothache tried to relieve the pain by treating the infected area
with moist heat. Will this treatment help? Why or why not?
5. Lungs expand as they fill with air. Exhaling decreases the
volume of the lungs. Describe the law that explains this biological
function?
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